KR101983700B1 - Use of known data for state signaling - Google Patents

Abstract

A system and method for fast recovery using transmission of known sequences to inform the quality of operating points. One method includes transmitting a first known sequence by a first transceiver during a first duration when identifying the following steps, i. E., Degradation at the operating point of the first transceiver: Responding by a second transceiver in a second known sequence during a second duration; Transmitting the second known sequence during the second duration when identifying a degradation in the operating point of the second transceiver and responding by the first transceiver to the first known sequence during the first duration . Here, the transceivers use the known sequence to recover the degradation at a higher rate than they could recover without receiving the known sequences.

Description

Use of known data for state signaling

This application claims priority from U.S. Provisional Patent Application No. 62 / 286,930, filed January 25, 2016, priority of U.S. Provisional Patent Application No. 62 / 317,509, filed April 2, 2016, and U.S. Provisional Patent Application No. 62 / 62 / 343,874, filed on even date herewith.

State signaling is typically used to control transceiver functions and to monitor health and status information. However, state signaling requires a working communication link, and prior art documents disclose a mechanism that enables state signaling when at a bad operating point that one or both of the link partners are unable to receive data It is not.

In one embodiment, the communication system is configured to use transmissions of known sequences to indicate the quality of operating points. The communication system includes first and second transceivers. The first transceiver is configured to transmit a first known sequence for a first duration in response to identifying a degradation in its operating point. Wherein the second transceiver is configured to respond with a second known sequence for a second duration in response to receiving the first known sequence, wherein each of the first duration and the second duration is responsive to receiving the first known sequence, Is longer than the round trip delay between the first transceiver and the second transceiver. And in response to identifying a degradation in the operating point of the second transceiver, the second transceiver is additionally configured to transmit the second known sequence during the second duration, after which the first transceiver And to respond with the first known sequence during the first duration.

In another embodiment, a method of utilizing the transmission of a known sequence to inform the quality of operating points of the first and second transceivers comprises the following steps: i. E. 1. A method comprising: transmitting, by a transceiver, a first known sequence for a first duration; And responding with a second known sequence for a second duration by the second transceiver when receiving the first known sequence, wherein each of the first duration and the second duration comprises the first transceiver and the second Than the round-trip delay between transceivers; And transmitting the second known sequence during the second duration when identifying a quality degradation at its operating point by the second transceiver, wherein the first known sequence is transmitted by the first transceiver during the first duration And responding with a sequence.

These embodiments are described by way of example only with reference to the accompanying drawings. No attempt is made to show the structural details of the embodiments in more detail than are necessary for a basic understanding of the embodiments.

Figure 1 shows a communication system using transmissions of known sequences to inform the quality of operating points.
Figure 2 shows an embodiment of a mode conversion canceller using known data for fast convergence.

In one embodiment, the transceiver receives a notification from its link partner that the partner is at a bad operating point. As a result, the transceiver begins transmitting the first known data for at least a first predefined minimum period, and then transmits a signal indicating that its receiver (receiver of the transmitter) is at a good operating point. The link partner is configured to operate in a similar manner when the link partner receives a notification from the transceiver that the transceiver is at a bad operating point. The link partner begins transmitting the second known data for at least a second predefined minimum period and sends a signal indicating that its receiver (the receiver of the link partner) is at a good operating point.

Figure 1 shows a communication system using transmissions of known sequences to inform the quality of operating points. The system includes a first transceiver 401 and a second transceiver 402 that communicate over a communication channel 403. In response to identifying a degradation in its operating point, the first transceiver 401 transmits a first known sequence for a first duration. Then, in response to receiving the first known sequence, the second transceiver 402 responds with a second known sequence for a second duration in response to receiving the first known sequence, And each of the second duration is longer than the loud trip delay between the first transceiver and the second transceiver. And in response to identifying a degradation in the operating point of the second transceiver (402), the second transceiver (402) transmits the second known sequence during the second duration, and then the first transceiver (401) responds with the first known sequence during the first duration.

The communication system may have various options. Optionally, the first transceiver uses the second known sequence to recover its quality degradation faster than it can recover without receiving the second known sequence. Additionally, the second transceiver may utilize the first known sequence to recover its degradation at a higher rate than it can recover without receiving the first known sequence. According to yet another option, the first and second transceivers each utilize the first and second known sequences to recover their degradation in less than one millisecond from the occurrence of their degradation. In one example, recovering degradation means that the communication system can successfully exchange data according to its expected performance. According to yet another option, the first and second transceivers each utilize the first and second known sequences to recover their degradation in less than 50 microseconds from the occurrence of their degradation.

Optionally, the first transceiver transmits a third known sequence after recovering from its degradation, and the second transceiver transmits a fourth known sequence after recovering from its degradation. Optionally, the first, second, third and fourth known sequences are different. In addition, the first and second transceivers may each include first and second scramblers, the first scrambler being known to the second transceiver, and the second scrambler being known to the first transceiver And the first, second, third and fourth known sequences are made on the basis of the scramblers. Additionally or alternatively, the first and second known sequences may be bitwise complement codewords of the idle sequence transmitted by the first and second transceivers, respectively, and each bitwise complement codeword may be in an idle sequence . Optionally, the third and fourth known sequences are idle sequences transmitted by the first and second transceivers, respectively. According to yet another option, the second transceiver starts transmitting data only after receiving the third known sequence, and the first transceiver starts transmitting data only after receiving the fourth known sequence do.

Optionally, the duration from identifying a quality degradation at the operating point of the first transceiver to initiating transmission of the first known sequence is such that the first transceiver is required to transmit a nominal data packet Is shorter than the duration. In addition, the first transceiver may initiate transmission of the first known sequence during the transmission of the data packet. According to yet another option, the duration from receiving the first known sequence to transmitting the second known sequence is less than the duration required for the second transceiver to transmit a nominal data packet short. Additionally, the second transceiver may initiate transmission of the second known sequence during the transmission of the data packet.

Optionally, the first and second durations are predetermined and equal. Optionally, both the first and second durations are longer than 0.1 microseconds and shorter than 500 microseconds. And optionally both of the first and second durations are longer than 0.1 microseconds and shorter than 20 microseconds.

In one example, the quality degradation is due to mode conversion of the common mode signal, and while facing quality degradation, the first and second transceivers do not meet their expected performance. In this example, the quality degradation at the operating point of the first transceiver may be due to mode conversion of the common mode signal and while the quality degradation is encountered, the first transceiver does not meet its expected performance . Additionally or alternatively, the quality degradation at the operating point of the second transceiver may be due to mode conversion of the common mode signal, and while facing a quality degradation, the second transceiver may determine its expected performance It does not meet.

The communication system may additionally include a retransmission module that requires transmission of packets that could not be transmitted while at least one of the first and second transceivers was not recovered from their degradation. And optionally, the first and second transceivers communicate over a differential communication channel that transmits data at a rate higher than 500 Mbps.

In one embodiment, a method of utilizing transmission of a known sequence to inform the quality of operating points of first and second transceivers communicating over a communication channel comprises the following steps. In step 1, when identifying the quality degradation at its operating point by the first transceiver, it transmits a first known sequence for a first duration. In step 2, upon receiving the first known sequence, the second transceiver responds with a second known sequence for a second duration, wherein each of the first duration and the second duration is responsive to the first transceiver, And the round trip delay between the first transceiver and the second transceiver. And in step 3, transmitting the second known sequence during the second duration when identifying a quality degradation at its operating point by the second transceiver, and transmitting the second known sequence during the first duration by the first transceiver And responds with the first known sequence.

The method optionally includes transmitting a third known sequence after recovery from its degradation by the first transceiver and transmitting a fourth known sequence after recovering from its degradation by the second transceiver . Optionally, the method further comprises transmitting data by the second transceiver only after receiving the third known sequence and transmitting data by the first transceiver only after receiving the fourth known sequence, .

The method may optionally use the second known sequence to recover from its degradation at a higher rate than could be recovered without the receiving of the second known sequence by the following step, i.e. the first transceiver Step < / RTI > Additionally or alternatively, the method may further comprise, by the second transceiver, the first known sequence to recover its degradation at a higher rate than it could recover without receiving the first known sequence Lt; / RTI > Optionally, the method further comprises, by the first and second transceivers, using the first and second known sequences, respectively, to recover their degradation in less than one millisecond from the occurrence of degradation, . According to yet another option, the method comprises using the first and second known sequences, respectively, to recover their quality degradation by less than 50 microseconds from the occurrence of their degradation by the first and second transceivers Step < / RTI >

In one example, the duration from identifying the quality degradation at the operating point of the first transceiver to initiating transmission of the first known sequence is determined by the duration that the first transceiver takes to transmit the packet It is shorter than the period. And optionally, the method further comprises transmitting packets that could not be transmitted while at least one of the first and second transceivers was not recovered from their degradation.

Figure 2 shows an embodiment of a mode conversion canceller using known data for fast convergence. The embodiment includes a receiver analog front end (Rx-AFE) 222 and a common mode sensor AFE (CMS-AFE) 222 coupled to a differential communication channel 210 coupled to the following elements, i. 222). ≪ / RTI > The Rx-AFE 222 supplies the received differential signal to a digital equalizer and / or digital canceller (DEDC) 131. The CMS-AFE 230 extracts a digital representation of the common mode signal of the received differential signal and provides a forward adaptive mode conversion canceller (FA-MCC) 132 for generating a compensation signal for mitigating differential interference. do. It should be noted that the compensation signal alleviates the differential interference when the compensation signal cancels at least some of the effects of the differential interference to an extent such that the transceiver can meet its expected performance. For example, if the transceiver is expected to support more than 200 Mb / s throughput, the compensation signal mitigates the differential interference when the transceiver can support 200 Mb / s throughput, and if the transceiver is capable of handling 200 Mb / / s < / RTI > throughput, the compensation signal does not mitigate the differential interference.

In response to receiving a notification that significant differential interference has occurred, the transceiver 130 informs the second transceiver 138 to transmit known data. The transceiver 130 may use the known data to improve the accuracy of its slicing error (which in some cases means to reduce the slicing error), so that the retransmission module 136 may use fixed data over a 2-millisecond window The FA-MCC 132 can be quickly adapted to a level that mitigates the severe differential interference of the FA-MCC 132 to such an extent that it can require retransmission of errored packets at a rate high enough to maintain the transmission rate Let's do it.

Optionally, the digital equalizer may be an adaptive digital equalizer, the digital canceller may be an adaptive digital canceller, and the DEDC may include both the adaptive digital equalizer and the adaptive digital canceller (ADEC) . In this case, the FA-MCC and the ADEC send the ROS to a slicer 133, which reconstructs the original transmission signal representation (ROS) and supplies the sliced symbols to the physical coding sublayer (PCS) 135 Can supply. The PCS 135 may provide a link layer component that extracts a bitstream from the sliced symbols and parses the sliced symbols into packets. Optionally, the link layer component comprises the retransmission module 136.

In general, the parameters of the differential communication channel are all unknown, and the transceiver 130 operates at a first packet loss rate in the absence of significant differential interference. Sometimes, the differential communication channel is subject to the severe differential interference, and the severe differential interference increases the packet loss rate of the transceiver 130 to a second packet loss rate of at least 10, 1000, and / or a million times . Additionally or alternatively, the severe differential interference may be caused by a mode transition of the common mode signal, and the transceiver may not meet its expected performance while facing interference that is considered to be severe differential interference .

Optionally, the FA-MCC 132 may be configured to allow the transceiver 130 to forward packets within a packet delay variation of less than 1 millisecond or even less than 50 microseconds with retransmissions made in response to the severe differential interference Converge within a short time. In addition, in response to receiving a notification that the severe differential interference has occurred, the FA-MCC 132 may reduce its adaptation step size (ADSS) by at least 50%, in order to quickly mitigate the effects of the severe differential interference. . Optionally, after mitigating the effects of the severe differential interference, the FA-MCC 132 may reduce its ADSS.

The elements used by the above embodiments may be implemented in various ways. The analog front end (e.g., Rx-AFE, Tx-AFE, and CMS-AFE) may be implemented using analog and / or analog and digital components. The buffers are implemented using a processor and a memory for storing data for accessing data via a communication channel, such as a parallel bus or a serial bus. The elements such as digital canceller, equalizer, DBF, FA-MCC, ADEC, DEDC, slicer, selector, error generator, scrambler, PCS, link layer module, retransmission module, controller and / And at least one processor for causing software elements, i. E. ASICs, FPGAs, processors, memory blocks, discrete circuits, integrated circuits, instructions stored in at least one memory block to execute, A non-transitory computer readable medium having computer executable instructions for causing a processor to perform certain operations, a computer having a processor and a program of instructions executable by the processor to cause the processor to perform certain operations when executed by the processor Readable medium, one or more processing units and A memory including instructions for a given operation and storing one or more programs configured for execution by the one or more processing units, a system including a data processing apparatus, and a processor executable by the data processing apparatus, And non-transient computer readable media for storing instructions that cause the data processing apparatus to perform certain operations.

In this description, reference to " one embodiment " means that the features mentioned may be included in at least one embodiment of the invention. Further, in this description, a separate reference to " one embodiment " or " some embodiments " does not necessarily refer to the same embodiment. In addition, references to "one embodiment" and "another embodiment" may not necessarily refer to different embodiments, but may be terms that are sometimes used to illustrate different embodiments of one embodiment.

The individual blocks shown in these figures may be functional in nature and, as a result, may not necessarily correspond to individual hardware elements. Although the methods disclosed herein have been described and illustrated with reference to particular steps performed in a particular order, it is to be understood that such steps are understood to form an equivalent way without departing from the teachings of the present embodiments, Subdivided and / or reordered to form an equivalent method without departing from the teachings of the embodiments. Accordingly, the order and grouping of the above steps are not intended to limit the present embodiments, unless specifically stated otherwise in the specification. Moreover, the methods and mechanisms of the embodiments will sometimes be described in singular form for clarity. However, some embodiments may involve multiple iterations of a method or multiple instantiations of a mechanism, unless otherwise noted. For example, when a processor is disclosed in one embodiment, the scope of the embodiment is intended to also cover the use of multiple processors.

Claims (22)

A communication system configured to utilize transmissions of known sequences to inform the quality of operating points,
A first transceiver configured to transmit a first known sequence for a first duration in response to identifying a degradation in the operating point of the first transceiver;
A second transceiver configured to respond with a second known sequence during a second duration in response to receipt of the first known sequence, each of the first and second duration being responsive to a first known sequence, Than round trip delay between
/ RTI >
Wherein communication between the first transceiver and the second transceiver is established over a communication channel,
In response to identifying a degradation in the operating point of the second transceiver, the second transceiver is additionally configured to transmit the second known sequence during the second duration, and then the first transceiver And to respond with the first known sequence during a first duration,
The first transceiver is configured to use the second known sequence to recover quality degradation at the operating point of the first transceiver at a higher rate than the first transceiver could recover without receiving the second known sequence Wherein the second transceiver is configured to receive the first known sequence and to recover from degradation at the operating point of the second transceiver at a higher rate than the second transceiver could recover, The communication system comprising: The method according to claim 1,
Wherein the first and second transceivers are configured to utilize the first and second known sequences, respectively, to recover quality degradation at the operating point of the first and second transceivers within less than one millisecond of occurrence of the quality degradation, Communication system. The method according to claim 1,
Wherein the first and second transceivers are configured to utilize the first and second known sequences, respectively, to recover the quality degradation at the operating point of the first and second transceivers within less than 50 microseconds from the occurrence of the quality degradation, Communication system. The method according to claim 1,
Wherein the first transceiver is configured to transmit a third known sequence after recovering quality degradation at an operating point of the first transceiver and the second transceiver is configured to recover quality degradation at the operating point of the second transceiver And to transmit a fourth known sequence. 5. The method of claim 4,
Wherein the first and second transceivers each include first and second scramblers, the first scrambler is known to the second transceiver, the second scrambler is known to the first transceiver, and the first And the second, third and fourth known sequences are different and are based on the first and second scramblers. 5. The method of claim 4,
Wherein the first and second known sequences are each a bitwise-complement-code-word of an idle sequence transmitted by the first and second transceivers, respectively. The method according to claim 6,
Wherein each bitwise complement code word transmitted by the first or second transceiver appears in a corresponding idle sequence sent by the first or second transceiver. 5. The method of claim 4,
The third and fourth known sequences are idle sequences each transmitted by the first transceiver and the second transceiver and the second transceiver is configured to start transmitting data only after receiving the third known sequence And the first transceiver is configured to start transmitting data only after receiving the fourth known sequence. The method according to claim 1,
Wherein the duration from the quality degradation at the operating point of the first transceiver to the start of transmission of the first known sequence is less than the duration required for the first transceiver to transmit a data packet, Communication system. 10. The method of claim 9,
Wherein the first transceiver is configured to initiate transmission of the first known sequence during transmission of a data packet. The method according to claim 1,
Wherein the duration from receiving the first known sequence to initiating transmission of the second known sequence is less than the duration required for the second transceiver to transmit a data packet. 12. The method of claim 11,
And the second transceiver is configured to initiate transmission of the second known sequence during transmission of a data packet. The method according to claim 1,
Both of the first and second durations being greater than 0.1 microseconds and less than 500 microseconds. The method according to claim 1,
Both of the first and second durations being greater than 0.1 microseconds and less than 20 microseconds. delete delete A method of utilizing transmissions of known sequences to inform qualities of operating points of first and second transceivers,
Wherein communication between the first transceiver and the second transceiver is established over a communication channel,
The method comprises:
Transmitting, by the first transceiver, a first known sequence for a first duration when identifying a degradation in the operating point of the first transceiver;
Responding with a second known sequence for a second duration by the second transceiver upon receiving the first known sequence, wherein each of the first duration and the second duration comprises: Than the round-trip delay between transceivers;
Wherein the first transceiver transmits the second known sequence during the second duration by the second transceiver when identifying a degradation in the operating point of the second transceiver, Responding with one known sequence; And
The second known sequence is utilized by the first transceiver to recover the quality degradation at the operating point of the first transceiver at a higher rate than the first transceiver could recover without receiving the second known sequence To the second transceiver to recover the quality degradation at the operating point of the second transceiver at a higher rate than the second transceiver could recover without receiving the first known sequence ≪ / RTI >
Using known transmissions of sequences to inform the quality of operating points of the first and second transceivers. 18. The method of claim 17,
Using the first and second known sequences, respectively, by the first and second transceivers to recover a quality degradation of the operating points of the first and second transceivers within less than one millisecond from the occurrence of the quality degradation;
The method further comprising using known transmissions of sequences to inform the quality of operating points of the first and second transceivers. 18. The method of claim 17,
Using said first and second known sequences, respectively, by said first and second transceivers to recover a quality degradation at an operating point of said first and second transceivers within less than 50 microseconds from the occurrence of said quality degradation, ;
The method further comprising using known transmissions of sequences to inform the quality of operating points of the first and second transceivers. 18. The method of claim 17,
The first transceiver transmits a third known sequence after recovering the quality degradation at the operating point of the first transceiver and the quality degradation at the operating point of the second transceiver by the second transceiver Transmitting, after recovering, a fourth known sequence;
The method further comprising using known transmissions of sequences to inform the quality of operating points of the first and second transceivers. 21. The method of claim 20,
Transmitting data by the second transceiver only after receiving the third known sequence, and transmitting data by the first transceiver only after receiving the fourth known sequence;
The method further comprising using known transmissions of sequences to inform the quality of operating points of the first and second transceivers. delete

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